SE460929B - SET AND DEVICE MEASURING THE VOLUME OF A VOLUME THAT FLOWS THROUGH A MEETING CHAMBER DURING A MEASURING PERIOD - Google Patents

Abstract

In a method for measuring the volume of a liquid flow through a measuring chamber (2) during a measuring period, a pulse generator (12) is caused to emit a number of pulses corresponding to the volume. In the measurement, the measuring period is divided into a number of measuring intervals. During each measuring interval, the pulses from the pulse generator (12) are detected, each detected pulse is multiplied by a flow correction factor, the corrected pulse values are added to a summation variable, and this summation variable is multiplied by a volume conversion factor for determining the liquid volume. The separate determined liquid volumes are thereafter summed up for all measuring intervals during the measuring period. A measuring apparatus for measuring the volume of a liquid flow through a measuring chamber (2) has a pulse generator (21, 23) for generating a number of pulses corresponding to the volume, has time base means (33) for dividing the measuring period into measuring intervals, memory means (34) for storing one or more correction factors, pulse-correcting computing means (24, 25) for multiplying each detected pulse by said one or more correction factors, adder means (26, 27) for adding the corrected pulse values, and multiplier means (35) for multiplying the added corrected pulse values by a volume conversion factor.

Description

460 92§ * 2 flows through the measuring chamber by counting the number of pulses emitted by the encoder during the measuring period and multiplying this number by the proportionality factor. Since the pulses from a measuring device described above are usually fed directly to a volume counter, it is suitable that the same number of pulses always corresponds to the same volume independent of the measuring device, so that the same factor for converting pulse number to volume can be used in all counters. connected. However, for design reasons and depending on the liquid for which the measuring device is used, in practice the conversion factor varies between different measuring devices. However, as shown in the above-mentioned German patent application, this problem can be solved by means of a correction unit arranged after the encoder, in which the counted number of pulses is multiplied by a set correction factor, so that the desired ratio between pulses and volume is obtained. Another known way of solving the problems is to set the stroke of the pistons so that one revolution of the shaft corresponds to a desired volume. In a known measuring device sold by the applicant, this is done manually by means of an eccentric unit. However, there are further problems and disadvantages with the devices and measuring methods described above which have not yet been given a satisfactory solution.

A design disadvantage is the devices described above for calibrating the measuring devices so that the desired ratio between pulse number and volume is obtained. The eccentric unit is complicated and includes many parts, which means that the assembly is time-consuming and extensive maintenance. Furthermore, both devices require manual calibration when the ratio between heart rate and volume changes due to aging and wear. A further disadvantage is that the devices are relatively easy to manipulate.

Other problems and disadvantages are related to the measurement accuracy. Of course, you want to achieve as high a measuring accuracy as possible, and for example measuring devices in petrol pumps, there are limits to how large the measuring error may be. Measuring devices known today per se have good measuring accuracy, but the size of the measuring error depends on the flow rate of the liquid, so that the measuring error is considerably larger at very small and at very high flow rates than at intermediate flow rates, which is not satisfactory. In addition, as the device ages and wears out, the measurement error increases, which means that the devices, as mentioned, must be recalibrated.

Another disadvantage of known measuring devices is that they do not take into account the temperature of the measured liquid. The volume of liquids is temperature-dependent, which means that if you refuel, for example, you get less energy per unit volume when the petrol has a higher temperature than when it has a lower temperature. It would therefore be fairer if the payment for petrol was made according to energy content instead of by volume. For this purpose, it is desirable that the measuring devices can also determine the volume corresponding to a predetermined standard temperature. The object of the present invention is thus to provide a new method and a new device for volume measurement which eliminates the above-mentioned problems and disadvantages. The object is achieved by means of the initially described method, which is characterized by the steps of detecting the pulses from the encoder during each measuring interval, and multiplying each individual detected pulse by a flow correction factor, which is selected from the sum of the corrected pulse values for a previous measurement range. corrected the pulse values to a sum variable and on the other hand determine the liquid volume during the current measuring range by multiplying the value of this sum variable by a volume conversion factor; and of the step of summing the liquid volume for all measurement intervals during the measurement period. In a further development of the invention, in each measuring interval each of the detected pulses is also corrected with a temperature correction factor, which is selected 460 92§i 4 from the temperature determined during the previous measuring interval, so that each pulse represents a volume at a predetermined standard temperature.

To eliminate the need for manual recalibration due to wear, each measurement interval is further corrected in each of the detected pulses by an aging correction factor, the magnitude of which depends on the total volume of liquid that has flowed through the measuring chamber.

The method according to the invention means that the measurement accuracy is improved, that the need for manual recalibration due to wear is eliminated and that it becomes possible to charge according to energy content and not according to the temperature-dependent volume. It also becomes more difficult to manipulate the device.

The device for carrying out the method is characterized by the memory means for storing one or more correction factors, multiplying means for multinlicating each pulse detected by the detecting means with one or more correction factors, adding means for adding the corrected pulse values and multiplying means for multiplying the sum of the sums. added corrected heart rate values with a volume conversion factor.

The device is primarily intended to be placed in measuring means at petrol stations and to be used for measuring the volume of fuel that is refueled, but it can also be used for measuring larger volumes, for example the volume of fuel that is transferred from a tanker to a tank or from a depot. to a tanker.

In the following, the present invention will be described with an exemplary embodiment with reference to the accompanying drawings. Fig. 1 is a schematic view of a device for volume measurement and Fig. 2 is a block diagram schematically showing the principle of the measurement according to the invention. 460 929 The measuring device shown in Fig. 1, which is generally designated by reference numeral 1, comprises a measuring chamber 2 and a space 3 for measuring equipment. The measuring chamber 2 and the space 3 are delimited by side walls 4 and separated by a wall S. The space 3 is further delimited upwards by a lid 6. In the measuring chamber 2 there are pistons not shown, the displacement of which is a function of the volume of liquid flowing through the measuring chamber. are mechanically connected to a rotatable shaft assembly 7, which comprises a first shaft 7a arranged in the measuring chamber and a shaft 7b arranged in the space 3. The first shaft 7a is provided with a holder 8, which carries an annular permanent magnet 9. In the space 3, the second shaft is rotatably mounted in a recessed part 10 of the partition wall 5.

The second shaft 7b carries in the same way as the holder 8 an annular permanent magnet 11, which is concentric with the magnet 9. The rotation of the shaft assembly 7 is detected by means of encoder means, which comprise a perforated disc 12, which is placed on the upper end of the shaft 7b, an optical transmitter (not shown) and an optical receiver (not shown) and with which the direction of rotation of the shaft can be determined. The optical receiver is connected via a line 13 to a calculation unit 14, which in turn is connected via a line 15 to a temperature sensor 16 arranged in the measuring chamber 2 and via lines (not shown) to units arranged outside the measuring device, such as a display unit and a central computer.

Fig. 2 schematically shows the structure of a measuring system, with which the volume of the liquid flowing through the measuring device during a measuring period can be determined. The measuring system comprises a first pulse sensor 20, which is arranged to emit a predetermined number of pulses per revolution which the shaft assembly 7 rotates in a first direction, which is, for example, equal to the direction in which the shaft assembly normally rotates when transmitting petrol from a leg. - sine reservoir at a petrol station to a vehicle's fuel tank. Connected to the encoder 20 is a first pulse detector 21, which is arranged to detect the pulses emitted by the first encoder 20. Correspondingly, there is a pulse sensor 22, which is arranged to emit the same predetermined number of pulses per revolution as the shaft assembly 7 rotates in a second direction, which is then equal to the direction in which the shaft assembly rotates when liquid flows back through the measuring device to the fuel reservoir. Connected to the second pulse sensor 22 is a second pulse detector 23, which is arranged to detect the pulses emitted by the second pulse sensor 22. In practice, the first and the second encoder are a single sensor whose direction of rotation is detected in some suitable way, but for the sake of clarity this is shown as two separate blocks. The two pulse detectors 21 and 23 are connected to their respective inputs to the calculation unit 14. To each input thereof a correction unit 24 and 25, respectively, are connected, the output of which is connected to an adder unit 26 and 27, respectively, which in turn are connected. with a pulse accumulator 28 and 29, respectively. The outputs of the pulse accumulators 28 and 29 are connected to the plus input and the minus input, respectively, of an adder unit 30. Its output is connected to a scaling unit 32. The calculation unit 14 further comprises a time base unit 33, which has an output of each pulse accumulator 28 and 29 and an output to a memory 34, which contains various correction factors used in the volume calculation and which is connected to the two correction units 24 and. The output of the calculation unit 14 is connected to an input of a counter, a computer or a corresponding unit, which in Fig. 2 is represented by a multiplier 35, in which conversion from pulse number to volume is performed and to which belongs a display (not shown) for presentation. tion of the measurement results.

In the following, the function of the measuring system shown in Fig. 2 will be described in more detail. The first encoder 20 thus generates a predetermined number of pulses per revolution which the shaft assembly 7 rotates. These pulses are detected by the first pulse detector 21 and fed to the input of the calculation unit 14. In the correction unit, each pulse is corrected or "multiplied" by one or more correction factors. As previously mentioned, the magnitude of the measurement error varies with the flow rate of the liquid. In other words, one revolution of the shaft unit does not correspond to exactly the same volume at different flow rates, therefore a flow correction is always performed in the correction unit 24. In memory 34 there is a list of the correction factors corresponding to different flow rates, all of which have a value close to l.

Preferably there is a correction factor for each liter per minute.

In order to be able to select a suitable correction factor for correcting a pulse in the correction unit 24, the measuring period during which the liquid volume flowing through the measuring device is measured is divided into a large number of measuring intervals which are very short, for example 50 ms and whose length determined by means of the time base unit 33. During this short measuring interval, the flow rate can be assumed to be approximately constant. Furthermore, the flow rate varies very little between successive measuring intervals. In one and the same measuring interval, the same correction factor can thus be used for all pulses that are detected during the interval.

The appropriate correction factor for a measurement interval is determined by summing the corrected pulse values of the pulses detected during a previous measurement interval, obtaining a value of the flow rate, which is used to retrieve the corresponding correction factor in the list in memory 34.

In addition to the flow rate correction, other corrections may be performed similarly in the correction unit 24. These corrections may include correction for the temperature of the liquid, the temperature being measured and a temperature corresponding correction factor being retrieved from a list in memory 34, and correction for the aging of the measuring means. , wherein a correction factor is used whose magnitude is a function of the volume of the liquid which has been measured in total with the measuring device. 460 92§ “8 Each corrected pulse value is fed to the adder unit 26, in which it is added to a first intermediate storage variable. Then, the integer value is formed by the value of the first intermediate storage variable, this integer value is subtracted from the first intermediate storage variable and added to a first sum variable or the pulse accumulator 28. Since the pulse values (equal to the correction factors) are approximately equal to 1 and these operations are performed for each pulse value fed to the adder unit, the integer value is always equal to 2, 1 or 0, which is schematically shown in the figure. In the pulse accumulator 28, the integer values from the adder 26 are summed during each measurement interval.

Pulses generated by the second encoder 22 are processed in the same way: the pulses are detected by the second pulse detector 23, which supplies them to the correction unit 25, in which each pulse is corrected or multiplied by the same correction factor retrieved from the memory 34 used in the correction unit. 24 for the same measuring range. Each corrected pulse value is fed to the adder unit 27 and added to a second intermediate storage variable.

Thereafter, the integer value of the value of the second intermediate storage variable is formed, subtracted from it and added to a second sum variable or the pulse accumulator 29. The pulse sums accumulated during each measurement interval in the pulse accumulators 28 and 29 are fed on signal from the time base unit 33 to an adder unit 39 plus minusingáng. In this case, the net number of pulses for the measuring interval is obtained. This number is added to a third sum variable in a scaling unit 32 and the value of the integer sum of the third sum variable is divided by a scale factor. Preferably, different scale factors are used if the net number of pulses is greater or less than 0, i.e. if the number of pulses in the first direction is greater or less than the number of pulses in the second direction.

In the first case, for example, the scale factor can be equal to. The scaling is performed to make the measuring device less sensitive to disturbance. Through the scaling, individual 460 929 9 erroneous pulses will have no effect because, for example, in the above-mentioned case with the scale factor 10, at least 10 pulses are required for some pulse to be output from the calculation unit 14. The rest at the integer division is stored in the third sum variable the state of the integer division is output at the output of the calculation unit 14 for transmission to the multiplier 35, in which the number of pulses determined during each measuring interval is multiplied by a volume conversion factor.

Finally, it should be mentioned that the flow correction factors for correcting the measurement error dependent on the flow rate are determined experimentally.

Claims (9)

4eo 92å I 10 15 20 25 30 35 10 PATENT REQUIREMENTS A method of measuring the volume of a liquid flowing through a measuring chamber (2) during a measuring period, which measurement is carried out by means of movable pistons placed in the measuring chamber, which are arranged to be displaced by the liquid, a rotatable shaft assembly ( 7), which is connected to the pistons and arranged to be brought into rotation thereof, and at least one encoder (12) which emits a predetermined number corresponding to the volume of pulses for each revolution which the shaft assembly (7) rotates in a first direction, which includes the steps of dividing the measurement period into a number of measurement intervals, detecting the pulses in each measurement interval and multiplying the detected pulses by a flow correction factor, characterized by the steps of multiplying each individual during each measurement interval. detected pulse with a flow correction factor selected from the sum of the corrected pulse values for a previous measurement interval, and add the corrected pulse values to a sum variable 1 and multiply the value of this sum variable by a volume conversion factor for determining the liquid volume during the current measuring range, and by the step of summing the liquid volumes for all measuring ranges during the measuring period. 2. A method according to claim 1, characterized in that the step of adding the corrected pulse values to the sum variable is performed by adding each corrected pulse value to an intermediate storage variable, by determining the integer value of the intermediate storage variable value, by subtracting this integer value from the intermediate storage variable and by adding this integer value to the sum variable. IN 3. A method according to claim 1 or 2, wherein the measurement is performed by means of two encoders, which emit a number of pulses corresponding to the volume during liquid flow in one or the other direction through the measuring chamber, characterized in that the steps of during each measurement interval, on the one hand, detect the pulses from the first and the second .., ..-......_...., .....-.-- ~ 10 15 20 25 30 35 '"460 929 11 the encoder, multiply each individual detected pulse by the flow correction factor, add the corrected pulse values of the first encoder to a first sum variable, add the corrected pulse values of the second encoder to a second sum variable, and subtract the second sum variable from the first sum variable multiply the value of this sum variable by the volume conversion factor. 4. A method according to claim 3, characterized in that the step of adding the corrected pulse values to the second sum variable is performed by adding each corrected pulse value to a second intermediate storage variable, by determining the integer value of the value of the second intermediate storage variable, by subtracting of this integer value from the second intermediate storage variable and by adding this integer value to the second sum variable. ' 5. A method according to any preceding claim, characterized in that the flow correction factor is in the range 0.0000-2.0000. 6. A method according to any preceding claim, drawing - knowing - the steps of dividing the value of the sum variable by an integer scale by a first scale factor, if the value of the sum variable is greater than 0, and by a second scale factor, if the value of the sum variable during each measurement interval is less than 0, partly set the sum variable equal to the rest at the integer division and partly multiply the result of the integer division by the volume conversion factor for determining the liquid volume. 7. A method according to any one of the preceding claims, characterized by the steps of correcting each detected pulse during each measuring interval with a temperature correction factor, which is selected on the basis of the temperature determined during the previous measuring interval. 8. A method according to any one of the preceding claims, characterized by the steps of correcting each detected pulse during each measuring interval with an aging correction factor, which is selected on the basis of the total volume of liquid which has flowed. through the measuring chamber. Device for measuring the volume of a liquid flowing through a measuring chamber (2) during a measuring period, which device has movable pistons placed in the measuring chamber, which are arranged to be displaced by the liquid, a rotatable shaft assembly (7) , which is connected to the pistons and arranged to be brought into rotation thereof, a pulse sensor (12) which emits a predetermined number of pulses for each revolution which the shaft assembly (7) rotates, detecting means (21, 23) for detecting the pulses emitted by the encoder (12) and time base means (33) for dividing the measuring period into measuring intervals, characterized by memory means (34) for storing flow correction factors, multiplying means (24, 25) for multiplying each of the detecting means (21, 23). ) detected pulse with a flow correction factor, adding means (26, 27) for adding the corrected pulse values and multiplying means (3) for multiplying the sum of the added corrected pulse values by one vol y conversion factor, and summing means for summing the liquid volumes for all measuring intervals during the measuring period.